U.S. patent number 7,629,929 [Application Number 11/526,457] was granted by the patent office on 2009-12-08 for antenna using proximity-coupled feed method, rfid tag having the same, and antenna impedance matching method thereof.
This patent grant is currently assigned to Electronics and Telecommunications Research Institute. Invention is credited to Gil-Young Choi, Won-Kyu Choi, Cheol-Sig Pyo, Chan-Soo Shin, Hae-Won Son.
United States Patent |
7,629,929 |
Son , et al. |
December 8, 2009 |
Antenna using proximity-coupled feed method, RFID tag having the
same, and antenna impedance matching method thereof
Abstract
An antenna, a RFID tag using the same, and an antenna impedance
matching method thereof are provided. The antenna includes: a
radiation patch for deciding a resonant frequency of the antenna; a
ground plate disposed in parallel to the radiation patch; and a
feeder disposed between the radiation patch and the ground plate in
parallel for providing a RF signal to an element connected to the
antenna, wherein the feeder includes a microstrip feed line
proximately coupled to the radiation patch by being formed
perpendicularly to the resonant length direction of the radiation
patch.
Inventors: |
Son; Hae-Won (Daejon,
KR), Choi; Won-Kyu (Daejon, KR), Shin;
Chan-Soo (Daejon, KR), Choi; Gil-Young (Daejon,
KR), Pyo; Cheol-Sig (Daejon, KR) |
Assignee: |
Electronics and Telecommunications
Research Institute (Daejeon, KR)
|
Family
ID: |
37910640 |
Appl.
No.: |
11/526,457 |
Filed: |
September 25, 2006 |
Prior Publication Data
|
|
|
|
Document
Identifier |
Publication Date |
|
US 20070080867 A1 |
Apr 12, 2007 |
|
Foreign Application Priority Data
|
|
|
|
|
Sep 26, 2005 [KR] |
|
|
10-2005-0089522 |
Mar 16, 2006 [KR] |
|
|
10-2006-0024514 |
|
Current U.S.
Class: |
343/700MS |
Current CPC
Class: |
H01Q
1/2208 (20130101); H01Q 1/38 (20130101); H01Q
9/0457 (20130101); H01Q 9/0421 (20130101); H01Q
9/0407 (20130101) |
Current International
Class: |
H01Q
1/38 (20060101) |
Field of
Search: |
;343/700MS,702,824-826,850,893 |
References Cited
[Referenced By]
U.S. Patent Documents
Foreign Patent Documents
|
|
|
|
|
|
|
04-369901 |
|
Dec 1992 |
|
JP |
|
10-098331 |
|
Apr 1998 |
|
JP |
|
1020000012767 |
|
Mar 2000 |
|
KR |
|
1020010088495 |
|
Sep 2001 |
|
KR |
|
Other References
"Increasing the Bandwidth of a Microstrip Antenna by Proximity
Coupling". D.M. Pozar. Electonics Letter Apr. 9, 1987. vol. 23, No.
8. pp. 368-369. cited by other.
|
Primary Examiner: Mancuso; Huedung
Attorney, Agent or Firm: Ladas & Parry LLP
Claims
What is claimed is:
1. An antenna, comprising: a radiation patch for deciding a
resonant frequency of the antenna; a ground plate disposed in
parallel to the radiation patch; and a feeder disposed between the
radiation patch and the ground plate in parallel for providing a RF
signal to an element connected to the antenna, wherein the feeder
includes: a microstrip feed line proximately coupled to the
radiation patch by being formed perpendicularly to the resonant
length direction of the radiation patch and a ground side disposed
to be separated in the ground plate direction from the feed line in
parallel wherein the ground side of the feeder is shorted from the
ground plate in a direct current (DC) manner.
2. The antenna as recited in claim 1, wherein the feeder further
includes: a dielectric substrate disposed between the radiation
patch and the ground plate.
3. The antenna as recited in claim 1, wherein the ground plate is
used as the ground side of the feeder.
4. The antenna as recited in claim 1, wherein a terminal for
connecting the element connected to the antenna is formed on one
end of the feed line.
5. The antenna as recited in claim 4, wherein the other end of the
feed line is opened or shorted.
6. The antenna as recited in claim 4, wherein a load is connected
to the other end of the feed line.
7. The antenna as recited in claim 6, wherein the load is a lumped
element or a distributed element.
8. The antenna as recited in claim 1, further comprising a shorting
means for shorting the radiation patch and the ground plate.
9. The antenna as recited in claim 8, wherein the shorting means is
a shorting plate or a shorting pin.
10. The antenna as recited in claim 1, wherein the feed line has a
meander structure.
11. The antenna as recited in claim 1, wherein a slot is formed at
the radiation patch.
12. The antenna as recited in claim 2, wherein the space between
the radiation patch and the ground plate is completely filled with
the dielectric substrate.
13. The antenna as recited in claim 6, wherein the impedance of the
antenna is controlled using a characteristic that an imaginary
number part of the antenna impedance varies according to an
impedance of the load.
14. An antenna, comprising: a radiation patch for deciding a
resonant frequency of the antenna; a ground plate disposed in
parallel to the radiation patch; and a feeder disposed between the
radiation patch and the ground plate in parallel for providing a RF
signal to an element connected to the antenna, wherein the feeder
includes: a microstrip feed line proximately coupled to the
radiation patch by being formed perpendicularly to the resonant
length direction of the radiation patch, and a ground side disposed
to be separated in the ground plate direction from the feed line in
parallel, wherein the ground side of the feeder is shorted from the
ground plate in an alternating current (AC) manner through a
capacitive coupling.
15. The antenna as recited in claim 14, wherein the feeder further
includes: a dielectric substrate disposed between the radiation
patch and the ground plate.
16. The antenna as recited in claim 14, wherein the ground plate is
used as the ground side of the feeder.
17. The antenna as recited in claim 14, wherein a terminal for
connecting the element connected to the antenna is formed on one
end of the feed line.
18. The antenna as recited in claim 17, wherein the other end of
the feed line is opened or shorted.
19. The antenna as recited in claim 17, wherein a load is connected
to the other end of the feed line.
20. The antenna as recited in claim 19, wherein the load is a
lumped element or a distributed element.
21. The antenna as recited in claim 14, further comprising a
shorting means for shorting the radiation patch and the ground
plate.
22. The antenna as recited in claim 21, wherein the shorting means
is a shorting plate or a shorting pin.
23. The antenna as recited in claim 14, wherein the feed line has a
meander structure.
24. The antenna as recited in claim 14, wherein a slot is formed at
the radiation patch.
25. The antenna as recited in claim 15, wherein the space between
the radiation patch and the ground plate is filled with the
dielectric substrate.
26. The antenna as recited in claim 19, wherein the impedance of
the antenna is controlled using a characteristic that a real number
part of the antenna impedance varies according to an impedance of
the load.
27. An antenna, comprising: a radiation patch for deciding a
resonant frequency of the antenna; a ground plate disposed in
parallel to the radiation patch; and a feeder disposed between the
radiation patch and the ground plate in parallel for providing a RF
signal to an element connected to the antenna, wherein the feeder
includes a microstrip feed line proximately coupled to the
radiation patch by being formed perpendicularly to the resonant
length direction of the radiation patch, and wherein the impedance
of the antenna is controlled using a characteristic that a real
number part of antenna impedance varies according to a coupling
capacitance between the radiation patch and the feed line where the
coupling capacitance decides a coupling amount of the feed line and
an equivalent impedance between the radiation patch and the ground
plate.
28. The antenna as recited in claim 27, wherein the impedance of
the antenna is controlled using the characteristic that the real
number part of the antenna impedance increases as the coupling
capacitance increases.
29. The antenna as recited in claim 27, wherein the impedance of
the antenna is controlled using a characteristic that the coupling
capacitance increases as the width of the feed line is widened.
30. The antenna as recited in claim 27, wherein the impedance of
the antenna is controlled using a characteristic that the coupling
capacitance increases as a distance between the radiation patch and
the feed line is reduced.
31. The antenna as recited in claim 27, wherein the impedance of
the antenna is controlled using the characteristic that the real
number part of the antenna impedance changes according to a
distance from a center of the resonant length direction of the
radiation patch to the feed line.
32. The antenna as recited in claim 31, wherein the impedance of
the antenna is controlled using a characteristic that the real
number part of the antenna impedance increases as a distance from a
center of the resonant length direction of the radiation patch to
the feed line increases.
33. The antenna as recited in claim 31, wherein the impedance of
the antenna is controlled using a characteristic that the real
number part of the antenna impedance varies according to a distance
from the shorting means to the feed line.
34. The antenna as recited in claim 33, wherein the impedance of
the antenna is controlled using a characteristic that the real
number part of the antenna impedance increases as a distance from
the shorting means to the feed line increases.
35. An antenna, comprising: a radiation patch for deciding a
resonant frequency of the antenna; a ground plate disposed in
parallel to the radiation patch; and a feeder disposed between the
radiation patch and the ground plate in parallel for providing a RF
signal to an element connected to the antenna, wherein the feeder
includes a microstrip feed line proximately coupled to the
radiation patch by being formed perpendicularly to the resonant
length direction of the radiation patch, and wherein the impedance
of the antenna is controlled using a characteristic that an
imaginary number part of the antenna impedance varies according to
a characteristic impedance of the feed line.
36. The antenna as recited in claim 35, wherein the impedance of
the antenna is controlled using a characteristic that an imaginary
number part of the antenna impedance varies according to the length
of the feed line.
37. The antenna as recited in claim 35, wherein the impedance of
the antenna is controlled using the characteristic that the
imaginary number part of the antenna impedance increases as the
coupling capacitance increases.
38. The antenna as recited in claim 35, wherein the impedance of
the antenna is controlled using a characteristic that the coupling
capacitance increases as the width of the feed line is widened.
39. The antenna as recited in claim 35, wherein the impedance of
the antenna is controlled using a characteristic that the coupling
capacitance increases as a distance between the radiation patch and
the feed line is reduced.
40. The antenna as recited in claim 35, wherein the impedance of
the antenna is controlled using the characteristic that the
imaginary number part of the antenna impedance changes according to
a distance from a center of the resonant length direction of the
radiation patch to the feed line.
41. The antenna as recited in claim 40, wherein the impedance of
the antenna is controlled using a characteristic that the imaginary
number part of the antenna impedance increases as a distance from a
center of the resonant length direction of the radiation patch to
the feed line increases.
42. The antenna as recited in claim 40, wherein the impedance of
the antenna is controlled using a characteristic that the imaginary
number part of the antenna impedance varies according to a distance
from the shorting means to the feed line.
43. The antenna as recited in claim 42, wherein the impedance of
the antenna is controlled using a characteristic that the imaginary
number part of the antenna impedance increases as a distance from
the shorting means to the feed line increases.
Description
FIELD OF THE INVENTION
The present invention relates to an antenna, an RFID tag, and an
impedance matching method; and, more particularly, to an antenna
using a proximity-coupled feed method, a radio frequency
identification (RFID) tag or transponder using the same, and an
antenna impedance matching method thereof.
DESCRIPTION OF RELATED ARTS
A radio frequency identification (RFID) tag is widely used with a
RFID reader or a RFID interrogator in various fields such as
materials management and security management. Generally, if an
object with an RFID tag attached is placed in the read zone of a
RFID reader, the RFID reader transmits an interrogation signal to
the RFID tag by modulating a radio frequency (RF) signal having a
predetermined carrier frequency, and the RFID tag responses the
interrogation signal transmitted from the RFID reader. That is, the
RFID reader transmits the interrogating signal to the RFID tag by
modulating a continuous electromagnetic wave having a predetermined
frequency. Then, the RFID tag modulates the electromagnetic wave
transmitted from the RFID reader using a back-scattering modulation
scheme and returns the back-scattering modulated electromagnetic
wave to the RFID reader in order to transmit the information stored
in an internal memory of the RF tag to the RFID reader. The
back-scattering modulation is a method of transmitting the
information of a RFID tag by scattering the electromagnetic wave
transmitted from the RFID reader, modulating the intensity or the
phase of the scattered electromagnetic wave and transmitting the
information of the RFID tag to the RFID reader.
A passive RFID tag uses the electromagnetic wave transmitted from
the RFID reader as a power source of itself by rectifying the
electromagnetic wave in order to obtain the driving power. In order
to normally drive the passive RFID tag, the intensity of the
electromagnetic wave transmitted from the RFID reader must be
stronger than a predetermined threshold value at a location where
the RFID tag is placed. That is, the read zone of the RFID reader
is limited by the intensity of the electromagnetic wave that is
transmitted from the RFID reader and reached at the RFID tag.
However, the transmitting power of the RFID reader cannot increase
unlimitedly because the transmitting power of the RFID reader is
restricted by the local regulation of each country such as federal
communication commission (FCC) of U.S. Therefore, in order to widen
the read zone without increasing the transmitting power of the RFID
reader, the RFID tag must effectively receive the electromagnetic
wave transmitted from the RFID reader.
As one of conventional methods for improving the efficiency of the
RFID tag, a method using an additional matching circuit was
introduced. Generally, the RFID tag includes an antenna, a RF
front-end, and a signal processor. The RF front-end and the signal
processor are manufactured in one chip. The conventional method
using the matching circuit maximizes the intensity of the signal
transmitted from the antenna to the RF front-end by performing
conjugate-matching of the antenna and the RF front-end using the
additional matching circuit. However, the additional matching
circuit occupies the large area in the chip because the matching
circuit consists of capacitors and inductors. Therefore, the
conventional method using the additional matching circuit has a
drawback in the views of integrity and a manufacturing cost.
SUMMARY OF THE INVENTION
It is, therefore, an object of the present invention to provide an
antenna having a broadband characteristic for unlimitedly and
independently controlling the resistance components and the
reactance components thereof by disposing a microstrip feed line
between a radiation patch and a ground plate to be perpendicular to
the resonant length direction of the radiation patch so as to be
proximity-coupled to the radiation patch.
It is another object of the present invention to provide a radio
frequency identification (RFID) tag that allows effective broadband
matching to a RF front-end having a large capacitance reactance
against resistance through the antenna.
In accordance with an aspect of the present invention, there is
provided an antenna including: a radiation patch for deciding a
resonant frequency of the antenna; a ground plate disposed in
parallel to the radiation patch; and a feeder disposed between the
radiation patch and the ground plate in parallel for providing a RF
signal to an element connected to the antenna, wherein the feeder
includes a microstrip feed line proximately coupled to the
radiation patch by being formed perpendicularly to the resonant
length direction of the radiation patch.
In accordance with another aspect of the present invention, there
is also provided a method of matching the impedance of the antenna
an antenna including: a radiation patch for deciding a resonant
frequency of the antenna; a ground plate disposed in parallel to
the radiation patch; and a feeder disposed between the radiation
patch and the ground plate in parallel for providing a RF signal to
an element connected to the antenna, wherein the feeder includes a
microstrip feed line proximately coupled to the grand plate by
being formed perpendicularly to the resonant length direction of
the radiation patch.
In accordance with yet another aspect of the present invention,
there is provided a radio frequency identification (RFID) tag
including: an antenna for receiving a radio frequency (RF) signal
transmitted from a RFID reader; a front-end for rectifying and
detecting the RF signal; and a signal processor connected to the RF
front-end, wherein the antenna includes: a radiation patch for
deciding a resonant frequency of the antenna; a ground plate
disposed in parallel to the radiation patch; and a feeder disposed
for providing a RF signal to the RF front-end through a microstrip
feed line proximately coupled to the radiation patch by being
formed perpendicularly to the resonant length direction of the
radiation patch.
In accordance with still another aspect of the present invention,
there is provided an impedance matching method for an antenna
having a radiation patch for deciding a resonant frequency of the
antenna, a ground plate disposed in parallel to the radiation
patch, and a microstrip feed line proximately connected to the
radiation patch by being disposed between the radiation patch and
the ground plate to be perpendicular to the resonant length
direction of the radiation patch, the method including the step of:
matching impedance using a characteristic that a real number part
of an antenna impendence varies according to a location of the feed
line in the resonant length direction of the radiation patch.
BRIEF DESCRIPTION OF THE DRAWINGS
The above and other objects and features of the present invention
will become better understood with regard to the following
description of the preferred embodiments given in conjunction with
the accompanying drawings, in which:
FIG. 1 is a block diagram of a RFID system 100 where the present
invention is applied;
FIG. 2 is an equivalent circuit diagram of the tag antenna 123 and
the RF front end 121 of FIG. 1;
FIG. 3 is a view illustrating a tag antenna 300 in accordance with
a first embodiment of the present invention;
FIG. 4 is a view of a tag antenna 400 using a proximity coupled
feed method in accordance with a second embodiment of the present
invention;
FIG. 5 is a view showing a tag antenna 500 using a proximity
coupled feed method in accordance with a third embodiment of the
present invention; and
FIG. 6 is a view showing a tag antenna 600 using a proximity
coupled feed method in accordance with a fourth embodiment of the
present invention.
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an antenna, a RFID tag using the same, an antenna
impedance matching method thereof in accordance with a preferred
embodiment of the present invention will be described in more
detail with reference to the accompanying drawings.
FIG. 1 is a block diagram of a RFID system 100 where the present
invention is applied.
Referring to FIG. 1, the RFID system 100 includes a RFID tag 120
for storing information thereof, a RFID reader 110 having an
analyzing and a decoding function, and a host computer (not shown)
for reading data from the RFID tag 120 through the RFID reader 110
and processing the read data.
The RFID reader 110 includes a RF transmitter 111, a RF receiver
112, and a reader antenna 113. The reader antenna 113 is
electrically connected to the RF transmitter 111 and the RF
receiver 112. The RFID reader 110 transmits a RF signal to the RFID
tag 120 through the RF transmitter 111 and the reader antenna 113.
The RFID reader 110 receives a RF signal from the RFID tag 120
through the reader antenna 113 and the RF receiver 112. As
introduced in U.S. Pat. No. 4,656,463, the structure of the RFID
reader 110 is well known to those skilled in the art. Therefore,
the detailed description thereof is omitted.
The RFID tag 120 includes a RF front-end 121, a signal processor
122 and a tag antenna 123 in accordance with an embodiment of the
present invention. In case of a passive RFID tag, the RF front-end
121 supplies a necessary power to the signal processor 122 by
transforming a received RF signal to a DC voltage. Also, the
front-end 121 extracts a baseband signal from the received RF
signal. As introduced in U.S. Pat. No. 6,028,564, the constitution
of the RF front-end is well known to those skilled in the art.
Therefore, detail description thereof is omitted. The signal
processor 122 also has a widely known constitution to those skilled
in the art as introduced in U.S. Pat. No. 5,942,987.
Hereinafter, the operations of the RFID system 100 will be
described. The RFID reader 110 sends an interrogation signal to the
RFID tag 120 by modulating a RF signal with a predetermined carrier
frequency. The RF signal created from the RF transmitter 111 of the
RFID reader 110 is externally transmitted through an antenna 113 as
the form of an electromagnetic wave. Then, the electromagnetic wave
130 is transmitted from the reader antenna 113 to the tag antenna
123. The tag antenna 123 transfers the received electromagnetic
wave 130 to the RF front-end 121. If the intensity of the RF signal
transferred to the RF front-end 121 is stronger than a minimum
requested power to drive the RFID tag 120, the RFID tag 120 reposes
to the interrogation signal transmitted from the RFID reader 110 by
modulating the electromagnetic wave 130 using the back-scattering
modulation.
In order to widen the read zone of the RFID reader 110, the
intensity of the electromagnetic wave 130 transmitted from the RFID
reader 110 must be strong enough to provide a driving power to the
RFID tag 120. Also, the electromagnetic wave 130 transmitted from
the RFID reader 110 must be transferred to the RF front-end 131
without any loss using the high efficient tag antenna 123. That is,
in order to provide the high efficiency to the tag antenna 123, the
carrier frequency of the RF reader 110 must have a resonant
characteristic and must be conjugate-matched with the RF front-end
121.
FIG. 2 is an equivalent circuit diagram of the tag antenna 123 and
the RF front end 121 of FIG. 1. The circuit includes a voltage
source V.sub..varies., an antenna impedance Z.sub.a and a RF
front-end impedance Z.sub.c. The voltage source V.sub..varies. and
the antenna impedance Z.sub.a are the equivalent circuit of the tag
antenna 123. The RF front-end impedance Z.sub.c is the equivalent
circuit of the RF front-end 121. The antenna impedance has a real
number part R.sub.a and an imaginary number part X.sub.a. The real
number part R.sub.a denotes the equivalent resistance of the tag
antenna 123, and the imaginary number part X.sub.a denotes the
equivalent reactance of the tag antenna 123. The RF front-end
impedance also has a real number part R.sub.c and an imaginary
number part X.sub.c. The real number part R.sub.c denotes the
equivalent resistance of the RF front-end 121, and the imaginary
number part X.sub.c denotes the equivalent reactance of the RF
front-end 121.
In general, the maximum power is transferred from the tag antenna
123 to the RF front-end 121 if the antenna impedance Z.sub.a and
the RF front-end impedance Z.sub.c are conjugate-matched. The
conjugate matching is to make two complex impedances to have the
same absolute impedance value and to have the opposite phases. That
is, if the impedance of the tag antenna 123 or the impedance of the
RF front-end 121 is controlled to be R.sub.a=R.sub.c, and
X.sub.a=-X.sub.c, the maximum power is transferred from the tag
antenna 123 to the RF front-end 121.
Generally, the RF front-end 121 of a passive or a semi-passive RFID
tag includes a rectifier circuit and a detector circuit using a
diode and does not include an additional matching circuit in order
to reduce the size of the chip thereof. Therefore, the impedance of
the RF front-end 121 has a complex impedance different from about
50.OMEGA. in general. Also, the impedance of the RF front-end 121
has a small resistance component R.sub.c and a large capacitive
reactance component X.sub.c in a ultra high frequency (UHF) band
due to the characteristics of the rectifier and the detector
circuit. Therefore, the antenna impedance Z.sub.a for the conjugate
matching must have a small resistance component R.sub.a and a large
inductive reactance component X.sub.a, and they must be resonated
by the frequency of the electromagnetic wave transmitted from the
RFID reader at the same time.
FIG. 3 is a view illustrating a tag antenna 300 in accordance with
a first embodiment of the present invention.
Referring to FIG. 3, the tag antenna 300 according to the present
embodiment includes a rectangular radiation patch 310 and a ground
plate 320 disposed to be parallel from the radiation patch 310. The
radiation patch 310 is proximity-coupled to a microstrip feed line
341. The direction 346 of the microstrip feed line 341 is
perpendicular to the resonant length direction 311 of the radiation
patch 310. That is, as shown in FIG. 3, if the resonant length
direction of the radiation patch 310 is a direction x, the
direction 346 of the feed line 341 is controlled to be in a
direction y. The radiation patch 310 and the ground plate 320 are
separated each other at a constant distance 351 in parallel, and
the predetermined portion or the entire of the radiation patch 310
and the ground plate 320 are filled with a predetermined dielectric
material 350 including air. The resonant frequency of the tag
antenna 300 is decided by the length 313 of the radiation patch
310. The width 314 of the radiation patch 310 lightly influences
the resonant frequency, comparatively. Generally, the resonant
frequency of the antenna becomes little bit smaller if the width
314 of the radiation patch 310 becomes wider.
In a conventional proximity coupled feed method, the direction of
the feed line is formed to be identical to the resonant length of
the radiation patch. Such a conventional proximity coupled feed
method is described in an article by D. M. Pozar, entitled
"Increasing the bandwidth of a microstrip antenna by proximity
coupling", Electronics Letters, vol. 23, No. 8, April 1987. In the
conventional proximity coupled feed method, the equivalent
impedance between the radiation patch and the ground plate which
are coupled to the feed line significantly vary according to the
coupling location on the feed line. Therefore, the resistance
component R.sub.a and the reactance component X.sub.a of the
antenna cannot be independently controlled. Also, it is very
difficult to make a small resistance component R.sub.a as small as
about several .OMEGA.s, which is required to a RFID tag antenna,
using the conventional proximity coupled feed method.
In the antenna according to the present embodiment, the direction
346 of the feed line is disposed perpendicular to the resonant
length direction 311 of the radiation patch. In this case, the
equivalent impedance between the radiation patch and the ground
patch coupled to the feed line is not significantly varied
according to the coupling location thereof on the feed line.
Therefore, the resistance component R.sub.a and the reactance
components X.sub.a of the antenna can be controlled independently
and unlimitedly. Also, it is possible to easily make the small
resistance component R.sub.a as small as about server .OMEGA.s,
which is required at the RFID tag antenna. For example, when the
resonate length direction 311 of the radiation patch 310 has a
symmetry structure with a center surface 330 as a central figure,
the equivalent impedance between the radiation patch 310 and the
ground plate 320 from the center surface 330 becomes about
0.OMEGA.. Therefore, the closer the feed line 341 is to the center
surface 330, the smaller the equivalent impedance coupled to the
feed line 341 can be obtained. By controlling the coupling location
of the feed line 341 as described above, it is easy to manufacture
the antenna having a small resistance component R.sub.a as small as
several .OMEGA.s. Also, the antenna according to the present
embodiment has a broadband characteristic like as a conventional
antenna using a conventional proximity coupled feed method.
As shown in FIG. 3, the feeder 340 of the antenna according to the
present embodiment includes a dielectric plate 342, a feed line 341
disposed at one side of the dielectric plate 342 and having a form
of a microstrip, and a ground side 343 disposed at the opposite
side from the side coupled to the dielectric plate 342. The feeder
340 is disposed between the radiation patch 310 and the ground
plate 320, and the ground side 343 of the feeder 340 is shorted
from the ground plate 340 in a direct current (DC), or in an
alternating current (AC) through a capacitive coupling. Also, the
ground plate 320 may be shared as the ground side 343 of the feeder
340. That is, the one metal plate can be used as the ground plate
and the ground side at the same time.
A terminal 344 is formed on a one end of the feeder 341, and the
terminal 344 is connected to the RF front-end 121. A load 345
having a predetermined value is formed at other end of the feed
line 341. Herein, the load 345 may be opened or shorted, or it is
obvious to those skilled in the art that various shapes of
well-known loads may be used as the load 345 such as a lumped
element and a distributed element.
When the antenna 300 according to the present embodiment is
resonated, the equivalent impedance between the radiation patch 310
and the ground plate 320 at the location of the feed line 341
mainly has resistance component, and the resistance component is
added to the feed line 341 through the capacitive coupling. The
amount of the capacitive coupling is decided by the coupling
capacitance between the feed line 341 and the radiation patch 310.
In FIG. 3, the amount of the coupling capacitance and the distance
from the center surface 330 of the radiation patch 310 to the feed
line 341 are major factors to decide the resistance component
R.sub.a of the entire antenna impedance. Generally, the longer the
distance between the center surface 330 and the feed line 341 is,
the larger the resistance component R.sub.a of the antenna
impedance becomes. Also, the larger the coupling capacitance
between the feed line 341 and the radiation patch 310 becomes, the
larger the resistance component R.sub.a of the antenna impedance
becomes. The coupling capacitance is decided by the line width 347
of the feed line, and the distance 348 between the feed line and
the radiation patch. Meanwhile, the reactance component X.sub.a of
the antenna impedance is decided mainly by the characteristic
impedance of the feed line 341, the value of the load 345, the
length of the feed line 341 from the load 345 to the feed terminal
344.
Therefore, the antenna according to the present invention allows
the reactance X.sub.a of the antenna impedance to be controlled by
controlling the characteristics impedance of the feed line 341, the
length of the feed line and the load 345. Also, the antenna
according to the present invention allows the resistance component
R.sub.a of the antenna impedance to be controlled by controlling
the location of the feed line in the resonant length direction of
the radiation patch, and by the coupling capacitance between the
feed line and the radiation patch. That is, it is possible to
achieve the effectively impedance matching to the RF front-end 121
that has predetermined impedance because the antenna according to
the present embodiment allows the resistance component R.sub.a and
the reactance component X.sub.a of the antenna impedance to be
controlled independently and unlimitedly.
Meanwhile, the length 313 of the radiation patch is decided for the
radiation patch 310 to have a resonant characteristic in an
operating frequency. It is obvious to those skilled in the art that
the length of the radiation patch can be reduced by about 1/2,
while the resonant frequency is sustained identically, by disposing
a shorting plate or a sequence of shorting pins between the
radiation patch 310 and the ground plate 320.
FIG. 4 is a view of a tag antenna 400 using a proximity coupled
feed method in accordance with a second embodiment of the present
invention.
Referring to FIG. 4, the tag antenna 400 according to the second
embodiment includes a radiation patch 410, a ground plate 420 and a
shorting plate 430. In the tag antenna 400 according to the second
embodiment, the length of the radiation patch 413 is reduced by
shorting the radiation patch 410 and the ground late 430 through
disposing the shorting plate 430 between the radiation patch 410
and the ground plate 420. The shorting plate 430 is disposed in a
perpendicular direction, which is a direction y, form the resonant
length direction 411 of the radiation patch 410 at one side corner
of the radiation patch 410. The width 431 of the shorting plate may
be different from the width 414 of the radiation patch. As shown in
FIG. 4, the equivalent impedance between the radiation patch 410
and the ground plate 420 becomes about 0.OMEGA.. Therefore, the
resistance component R.sub.a of the antenna impedance is decided by
the coupling capacitance between the radiation patch 410 and the
feed line 441, and by the distance 431 between the shorting plate
430 and the feed line 431.
FIG. 5 is a view showing a tag antenna 500 using a proximity
coupled feed method in accordance with a third embodiment of the
present invention. The tag antenna 500 according to the third
embodiment includes a radiation patch 510, a ground plate 520 and a
plurality of shorting pins 530. In the tag antenna 500 according to
the third embodiment, the length of the radiation patch is reduced
by shorting the radiation patch 510 and the ground plate 520 by
disposing a sequence of the shorting pins 530 between the radiation
patch 510 and the ground plate 520. The shorting pins 530 are
disposed to be perpendicularly from the resonant length direction
511 of the radiation patch 510 at one side corner of the radiation
patch 510. As shown in FIG. 5, the equivalent impedance between the
radiation patch 510 and the ground plate 520 at the disposing
location of the shorting pins becomes about 0.OMEGA.. Therefore,
the resistance component R.sub.a of the antenna impedance is
decided by the coupling capacitance between the radiation patch 510
and the feed line 541, and by the distance 431 between the location
of the shorting pins 530 and the feed line 531 in FIG. 5.
As shown in FIG. 5, the feed line 541 has a meander structure
although the feed lines 341 and 441 have a shape of a straight line
in FIGS. 3 and 4. In order to reduce the size of the feed line, it
is obvious to those skilled in the art that the feed line may have
a meander structure as shown in FIG. 5 or the feed line may be
manufactured to have various shapes.
Also, it is obvious to those skilled in the art that the size of
the feeder may be reduced by forming a slot at the radiation patch
or increasing relative dielectric constant of the dielectric
filling between the radiation patch and the ground plate.
FIG. 6 is a view showing a tag antenna 600 using a proximity
coupled feed method in accordance with a fourth embodiment of the
present invention. Unlike from the other antennas shown in FIGS. 3
to 5, the ground side of the feeder 640 is shorted from the
radiation patch 610 in a DC manner, or shorted through the
capacitive coupling in an AC manner in the tag antenna 600 of FIG.
6. Also, the radiation patch 610 may be shared as the ground side
of the feeder. As shown in FIG. 6, the ground plate 620 is
proximity-coupled to the feed line 641. The operations and the
effects of the present invention described with reference to FIGS.
3 to 5 are identically applied into the tag antenna 600 of FIG.
6.
As described above, the microstrip feed line is disposed between
the radiation patch and the ground plate to be perpendicular from
the resonant length direction of the radiation patch so as to be
proximity coupled to the radiation patch in the antenna according
to the present invention. Therefore, the resistance component and
the reactance component of the antenna impedance can be controlled
independently and unlimitedly according to the present
invention.
Therefore, it is an object of the present invention to a low cost
planner antenna capable of an effective broadband matching to an
antenna coupling element having a predetermined impedance using a
proximity-coupled feed method. Also, it is another object of the
present invention to provide an antenna capable of an effective
broadband matching to a RF front-end having a large capacitive
reactance against the resistance, and a RFID tag using the
same.
The antenna using the proximity-coupled feed method and the RFID
tag using the same have the resonant characteristic and the
broadband characteristics and also provides superior
characteristics even when the antenna is attached to a metal
surface or a material having a high dielectric constant.
It is still another object of the present invention to provide an
antenna impedance matching method using a proximity-coupled feed
method.
The present application contains subject matter related to Korean
patent application Nos. KR 2005-0089522 and 2006-0024514, filed
with the Korean patent office on Nov. 26, 2005, and Mar. 16, 2006,
the entire contents of which being incorporated herein by
reference.
While the present invention has been described with respect to
certain preferred embodiments, it will be apparent to those skilled
in the art that various changes and modifications may be made
without departing from the spirits and scope of the invention as
defined in the following claims.
* * * * *